The distribution and transformation of iron (Fe), manganese (Mn), and aluminum (Al) in abandoned coal mine drainage in Korea were investigated, focusing on their size fractions and environmental behavior. Field samples and synthetically prepared drainage were analyzed by separating metal fractions into four categories: dissolved (<50 kDa), colloidal (50 kDa~0.45 μm), particulate (>0.45 μm), and precipitated forms. In field samples, most metals were present in the dissolved fraction. Laboratory experiments confirmed that under acidic conditions (pH 4), the metals remained primarily in the dissolved state, whereas under neutral conditions (pH 7), rapid coagulation and precipitation occurred, especially for Fe3+ and Al3+. Temperature had a notable impact on Fe, with higher temperatures accelerating aggregation and precipitation, while Al distribution was less temperature-dependent. The presence of iron-oxidizing bacteria, Acidithiobacillus ferrooxidans, significantly enhanced Fe oxidation and precipitation. The higher the bacterial inoculum, the greater the proportion of Fe transformed into particulate and precipitated forms, even at lower pH values. The results suggest that such bacteria contribute to the formation of yellow-boy, which can cause aesthetic and environmental issues downstream. The results provide information on the mechanisms behind yellow-boy and white-boy formation and can serve as a practical reference for the improved operation and discharge management of mine drainage treatment systems.